Learning The Hard Way That DNS Is Insecure: Attack Details Now Public

0

There are times when the full disclosure of a security vulnerability works well for everybody, and there are times when it does not. One such case where it hasn’t worked out well is with the DNS security vulnerabilities recently ‘discovered’ by security researcher Dan Kaminsky. Some weeks ago after he called a press conference with the organizers of the Black Hat conference vendors rushed to work out the details of the bug (he was intentionally vague with the details) and release patches. The full details of the attack were supposed to be revealed by Kaminsky at Black Hat on the 6th of August, but in the interim the full details of the attack have leaked – exposing a large number of the DNS servers on the web to poisoning attacks.

The attack relies on poor random sequence generation and poor port selection used in parent lookup requests. A DNS server querying up the chain for the response to a request authorizes the response based on the port it is being received on (which is usually easy to guess) and a sequence ID – which is often not very random. An attacker simply sends thousands of ‘response’ packets back to the requesting server after forcing a lookup, and if the correct sequence number is guessed then the server will cache the response for as long as the TTL specifies.

The attack is incredibly simple, and exploits a core weakness in the way that the domain name system operates. This attack is not new either, as a number of other researchers have pointed out. The flaws in the DNS system have long been known, and script for guessing sequence numbers for forged responses have been around for years. DNS poisoning attacks are difficult to detect and can lead to simple large-scale phishing attacks on vulnerable servers.

If you are running a DNS server the best course of action is to contact your vendor or to point your parent requests to OpenDNS, who are not vulnerable to this method. A full description of the attack is included below:

Reliable
DNS Forgery in 2008: Kaminskyâ€™s Discovery
from Matasano Chargen by ecopeland
0.
The cat is out of the bag. Yes, Halvar Flake figured out the flaw Dan
Kaminsky will announce at Black Hat.
1.
Pretend for the moment that you know only the basic function of DNS â€”
that it translates WWW.VICTIM.COM into 1.2.3.4. The code that does this
is called a resolver. Each time the resolver contacts the DNS to
translate names to addresses, it creates a packet called a query. The
exchange of packets is called a transaction. Since the number of
packets flying about on the internet requires scientific notation to
express, you can imagine there has to be some way of not mixing them
up.
Bob goes to to a deli, to get a sandwich. Bob walks up to the counter,
takes a pointy ticket from a round red dispenser. The ticket has a
number on it. This will be Bobâ€™s unique identifier for his sandwich
acquisition transaction. Note that the number will probably be used
twice â€” once when he is called to the counter to place his order and
again when heâ€™s called back to get his sandwich. If youâ€™re wondering,
Bob likes ham on rye with no onions.
If youâ€™ve got this, you have the concept of transaction IDs, which are
numbers assigned to keep different transactions in order. Conveniently,
the first sixteen bits of a DNS packet is just such a unique
identifier. Itâ€™s called a query id (QID). And with the efficiency of
the deli, the QID is used for multiple transactions.
2.
Until very recently, there were two basic classes of DNS
vulnerabilities. One of them involves mucking about with the QID in DNS
packets and the other requires you to know the Deep Magic.
First, QIDs.
Bobâ€™s a resolver and Alice is a content DNS server. Bob asks Alice for
the address of WWW.VICTIM.COM. The answer is 1.2.3.4. Mallory would
like the answer to be 6.6.6.0.
It is a (now not) secret shame of mine that for a great deal of my
career, creating and sending packets was, to me, Deep Magic. Then it
became part of my job, and I learned that it is surprisingly trivial.
So put aside the idea that forging IP packets is the hard part of
poisoning DNS. If Iâ€™m Mallory and Iâ€™m attacking Bob, how can he
distinguish my packets from Aliceâ€™s? Because I canâ€™t see the QID in his
request, and the QID in my response wonâ€™t match. The QID is the only
thing protecting the DNS from Mallory (me).
QID attacks began in the olden days, when BIND simply incremented the
QID with every query response. If you can remember 1995, hereâ€™s a
workable DNS attack. Think fast: 9372 + 1. Did you get 9372, or even
miss and get 9373? You win, Alice loses. Mallory sends a constant
stream of DNS responses for WWW.VICTIM.COM. All are quietly discarded
â€”- until Mallory gets Bob to query for WWW.VICTIM.COM. If Malloryâ€™s
response gets to your computer before the legitimate response arrives
from your ISPâ€™s name server, you will be redirected where Mallory tells
you youâ€™re going.
Obvious fix: you want the QID be randomly generated. Now Alice and
Mallory are in a race. Alice sees Bobâ€™s request and knows the QID.
Mallory has to guess it. The first one to land a packet with the
correct QID wins. Randomized QIDs give Alice a big advantage in this
race.
But thereâ€™s a bunch more problems here: * If you convince Bob to ask
Alice the same question 1000 times all at once, and Bob uses a
different QID for each packet, you made the race 1000 times easier for
Mallory to win. * If Bob uses a crappy random number generator, Mallory
can get Bob to ask for names she controls, like WWW.EVIL.COM, and watch
how the QIDs bounce around; eventually, sheâ€™ll break the RNG and be
able to predict its outputs. * 16 bits just isnâ€™t big enough to provide
real security at the traffic rates we deal with in 2008.
Your computerâ€™s resolver is probably a stub. Which means it wonâ€™t
really save the response. You donâ€™t want it to. The stub asks a real
DNS server, probably run by your ISP. That server doesnâ€™t know
everything. It canâ€™t, and shouldnâ€™t, because the whole idea of DNS is
to compensate for the organic and shifting
nature of internet naming and addressing. Frequently, that server has
to go ask another, and so on. The cool kids call this â€œrecursionâ€.
Responses carry another value, too, called a time to live (TTL). This
number tells your name server how long to cache the answer. Why?
Because they deal with zillions of queries. Whoever wins the race
between Alice and Mallory, their answer gets cached. All subsequent
responses will be dropped. All future requests for that same data,
within the TTL, come from that answer. This is good for whoever wins
the race. If Alice wins, it means Mallory canâ€™t poison the cache for
that name. If Mallory wins, the next 10,000 or so people that ask that
cache where WWW.VICTIM.COM is go to 6.6.6.0.
3.
Then thereâ€™s that other set of DNS vulnerabilities. These require you
to pay attention in class. They havenâ€™t really been talked about since
1997. And theyâ€™re hard to find, because you have to understand how DNS
works. In other words, you have to be completely crazy. Lazlo Hollyfeld
crazy. Iâ€™m speaking of course of RRset poisoning.
DNS has a complicated architecture. Not only that, but not all name
servers run the same code. So not all of them implement DNS in exactly
the same way. And not only that, but not all name servers are
configured properly.
I just described a QID attack that poisons the name serverâ€™s cache.
This attack requires speed, agility and luck, because if the â€œrealâ€
answer happens to arrive before your spoofed one, youâ€™re locked out.
Fortunately for those of you that have a time machine, some versions of
DNS provide you with another way to poison the name serverâ€™s cache
anyway. To explain it, I will have to explain more about the format of
a DNS packet.
DNS packets are variable in length and consist of a header, some flags
and resource records (RRs). RRs are where the goods ride around. There
are up to three sets of RRs in a DNS packet, along with the original
query. These are: * Answer RRâ€™s, which contain the answer to whatever
question you asked (such as the A record that says WWW.VICTIM.COM is
1.2.3.4) * Authority RRâ€™s, which tell resolvers which name servers to
refer to to get the complete answer for a question * Additional RRâ€™s,
sometimes called â€œglueâ€, which contain any additional information
needed to make the response effective.
A word about the Additional RRâ€™s. Think about an NS record, like the
one that COMâ€™s name server uses to tell us that, to find out where
WWW.VICTIM.COM is, you have to ask NS1.VICTIM.COM. Thatâ€™s good to know,
but itâ€™s not going to help you unless you know where to find
NS1.VICTIM.COM. Names are not addresses. This is a chicken and egg
problem. The answer is, you provide both the NS record pointing
VICTIM.COM to NS1.VICTIM.COM, and the A record pointing NS1.VICTIM.COM
to 1.2.3.1.
Now, letâ€™s party like itâ€™s 1995.
Download the source code for a DNS implementation and hack it up such
that every time it sends out a response, it also sends out a little bit
of evil â€” an extra Additional RR with bad information. Then letâ€™s set
up an evil server with it, and register it as EVIL.COM. Now get a bunch
of web pages up with IMG tags pointing to names hosted at that server.
Bob innocently loads up a page with the malicious tags which coerces
his browser resolve that name. Bob asks Alice to resolve that name.
Here comes recursion: eventually the query arrives at our evil server.
Which sends back a response with an unexpected (evil) Additional RR.
If Aliceâ€™s cache honors the unexpected record, itâ€™s 1995 â€”- buy CSCO!
â€”- and you just poisoned their cache. Worse, it will replace the â€œrealâ€
data already in the cache with the fake data. You asked where
WWW.EVIL.COM was (or rather, the image tags did). But Alice also â€œfound
outâ€ where WWW.VICTIM.COM was: 6.6.6.0. Every resolver that points to
that name server will now gladly forward you to the website of the
beast.
4.
Itâ€™s not 1995. Itâ€™s 2008. There are fixes for the attacks I have
described.
Fix 1:
The QID race is fixed with random IDs, and by using a strong random
number generator and being careful with the state you keep for queries.
16 bit query IDs are still too short, which fills us with dread. There
are hacks to get around this. For instance, DJBDNS randomizes the
source port on requests as well, and thus wonâ€™t honor responses unless
they come from someone who guesses the ~16 bit source port. This brings
us close to 32 bits, which is much harder to guess.
Fix 2:
The RR set poisoning attack is fixed by bailiwick checking, which is a
quirky way of saying that resolvers simply remember that if theyâ€™re
asking where WWW.VICTIM.COM is, theyâ€™re not interested in caching a new
address for WWW.GOOGLE.COM in the same transaction.
Remember how these fixes work. Theyâ€™re very important.
And so we arrive at the present day.
5.
Letâ€™s try again to convince Bob that WWW.VICTIM.COM is 6.6.6.0.
This time though, instead of getting Bob to look up WWW.VICTIM.COM and
then beating Alice in the race, or getting Bob to look up WWW.EVIL.COM
and slipping strychnine into his ham sandwich, weâ€™re going to be clever
(sneaky).
Get Bob to look up AAAAA.VICTIM.COM. Race Alice. Aliceâ€™s answer is
NXDOMAIN, because thereâ€™s no such name as AAAAA.VICTIM.COM. Mallory has
an answer. Weâ€™ll come back to it. Alice has an advantage in the race,
and so she likely beats Mallory. NXDOMAIN for AAAAA.VICTIM.COM.
Aliceâ€™s advantage is not insurmountable. Mallory repeats with
AAAAB.VICTIM.COM. Then AAAAC.VICTIM.COM. And so on. Sometime, perhaps
around CXOPQ.VICTIM.COM, Mallory wins! Bob believes CXOPQ.VICTIM.COM is
6.6.6.0!
Poisoning CXOPQ.VICTIM.COM is not super valuable to Mallory. But
Mallory has another trick up her sleeve. Because her response didnâ€™t
just say CXOPQ.VICTIM.COM was 6.6.6.0. It also contained Additional RRs
pointing WWW.VICTIM.COM to 6.6.6.0. Those records are in-bailiwick: Bob
is in fact interested in VICTIM.COM for this query. Mallory has
combined attack #1 with attack #2, defeating fix #1 and fix #2. Mallory
can conduct this attack in less than 10 seconds on a fast Internet link.